Bending Behavior of Zinc‐Coated Hot Stamping Steels

An investigation on the thermal property, fracture mechanism of substrate and coating layer, liquid‐metal embrittlement (LME) crack, coating layer morphology, microstructure, and hardness of Zn‐coated hot‐stamping steel is presented. The effect of forming temperature on the LME is studied. The crack mechanism of substrate at elevated temperature is ductile fracture with various‐sized dimples. The inclusions in the dimples are also detected and researched. However, the fracture mechanism of coating layer and weld spot is different from that of substrate. At high temperature, the liquid Zn invades into the substrate with oxidation reaction, which reduces the thermal formability. The complex chemical reaction and different phase formation occur in the coating layer. The coating layer breaks and peels off from the substrate with sharp edge, indicating brittle fracture. The phase of substrate mainly transforms into martensite phase with the microhardness Vickers hardness 0.2 of 410–490.

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of Hot Forming of Zn‐Coated Hot‐Stamping Steel

Ma,

Li,

Zheng

et al. 2024

“…They found that the increase in annealing time can eliminate the liquid phase and prevent the LMIE effectively. Hofer et al [ 20 ] analyzed the bending performance of the hot stamping steel with Zn coating. The crack initiation and propagation until failure were studied.…”

Section: Introductionmentioning

confidence: 99%

Effect of Heat Treatment on the Formability of Zn‐Coated Hot Stamping Steel

Zheng

et al. 2022

Herein, the effect of heat treatment with die quenching on Zn‐coated hot stamping steel is analyzed. Heating temperatures are 850, 880, 900, and 930 °C, and soaking times are 4 and 8 min. Then, microstructure, hardness, coating layer morphology, element diffusion and distribution, formation of microcrack and microvoid, and oxidation are analyzed. Results reveal that as heating temperature increases, the Vickers hardness of Zn‐coated hot stamping steel increases when soaking time is 4 min, while it decreases when soaking time is 8 min. The least average hardness value is still larger than 460, resulting from the formation of the martensitic phase. The diffusion tends to be significant as heating temperature and soaking time increase. Both the diffusion and the evaporation affect the thickness of the coating layer remarkably. The average layer thickness is at least 18.2 μm. Microcrack generates in the coating layer due to different thermal expansions between substrate and coating layer and the melting of Zn or Zn–Fe binary phase with high content of Zn. Microvoid forms in the coating layer, resulting from the Kirkendall effect and oxidation of the Zn element. Moreover, with the increase in heating temperature and soaking time, Fe2O3 is also generated on the coating surface along with ZnO.

“…The mechanism of embrittlement crack induced by liquid metal was mainly analyzed in hot stamping process. Hofer et al [18] researched the bending performance of hot DOI: 10.1002/srin.202100474 Herein, the effect of process parameters on the formability of Zn-coated stamping steel is analyzed, including heating temperature, soaking time, forming temperature, deformation level, and strain rate. The studied heating temperature ranges from 850 to 930 C; the soaking time ranges from 3 to 7 min; the deformation level ranges from 10% to the break; and the strain rate ranges from 0.1 to 10 s À1 .…”

Section: Introductionmentioning

confidence: 99%

“…The mechanism of embrittlement crack induced by liquid metal was mainly analyzed in hot stamping process. Hofer et al [ 18 ] researched the bending performance of hot stamping steel with Zn coating layer. The effect of decarburization, second phase, grain size, and nonmetallic inclusions on the bendability was analyzed.…”

Section: Introductionmentioning

confidence: 99%

Influence of Process Parameters on the Formability of Zn‐Coated Hot Stamping Steel

Rong

et al. 2021

Herein, the effect of process parameters on the formability of Zn‐coated stamping steel is analyzed, including heating temperature, soaking time, forming temperature, deformation level, and strain rate. The studied heating temperature ranges from 850 to 930 °C; the soaking time ranges from 3 to 7 min; the deformation level ranges from 10% to the break; and the strain rate ranges from 0.1 to 10 s−1. The thermal mechanical property is analyzed and fitted using the power model of allometric equation. The length of microcrack is measured using scanning electron microscope (SEM). It can be concluded that the true stress decreases with the increase of the heating temperature and soaking time. The decrease of the forming temperature and the increase of the strain rate lead to the increase of the true stress. The critical strain in the thermal tension process is about 0.35. The length of microcrack is below 10 μm for most of the cases. The optimal process parameters are proposed. The heat temperature should be at the range of 850−900 °C. The soaking time should not be larger than 5 min. The fracture is typical ductile fracture with dimples, resulting from the growth and emerging of microvoids.